Cellular Model of p21-Induced Senescence.

Cellular senescence is a unique process of normal physiology, from embryonic development to aging, also known for its association with a broad range of pathological conditions. Therefore a reliable model of cellular senescence remains an indispensable tool for the investigation of senescence-associated changes and human disease. Here we describe a model of HT1080 fibrosarcoma cells with an inducible senescence phenotype. These cells are equipped with the lac repressor and exogenous p21 under the control of a lac repressor regulated promoter. The senescent phenotype is induced in these cells by isopropyl-ß-D-thiogalactopyranoside (IPTG)-inducible expression of senescence-associated cell cycle inhibitor p21Waf1/Cip1/Sdi1.

Cyclin-dependent kinase 8 mediates chemotherapy-induced tumor-promoting paracrine activities.

Conventional chemotherapy not only kills tumor cells but also changes gene expression in treatment-damaged tissues, inducing production of multiple tumor-supporting secreted factors. This secretory phenotype was found here to be mediated in part by a damage-inducible cell-cycle inhibitor p21 (CDKN1A). We developed small-molecule compounds that inhibit damage-induced transcription downstream of p21. These compounds were identified as selective inhibitors of a transcription-regulating kinase CDK8 and its isoform CDK19. Remarkably, p21 was found to bind to CDK8 and stimulate its kinase activity. p21 and CDK8 also cooperate in the formation of internucleolar bodies, where both proteins accumulate. A CDK8 inhibitor suppresses damage-induced tumor-promoting paracrine activities of tumor cells and normal fibroblasts and reverses the increase in tumor engraftment and serum mitogenic activity in mice pretreated with a chemotherapeutic drug. The inhibitor also increases the efficacy of chemotherapy against xenografts formed by tumor cell/fibroblast mixtures. Microarray data analysis revealed striking correlations between CDK8 expression and poor survival in breast and ovarian cancers. CDK8 inhibition offers a promising approach to increasing the efficacy of cancer chemotherapy.

Proteomic analysis of factors released from p21-overexpressing tumour cells.

The p21Waf1/Cip1/Sdi1 cyclin-dependent kinase inhibitor is a key regulator of cell cycle progression and has also been observed to influence the expression of genes associated with several age-related disorders. Previous work has shown that expression of p21 in tumour cells mediates an antiapoptotic and mitogenic paracrine effect, which is in contrast to the arrested state of p21-expressing cells. Here, we have employed SELDI-MS technology to characterise, at a proteomic level, factors released from HT-1080 human fibrosarcoma cells displaying inducible p21 expression. Conditioned media from induced and noninduced cells were profiled on a range of diverse ProteinChip arrays and subjected to SELDI-MS analysis. Evaluation of proteins binding onto IMAC, Q10 or CM10 surfaces led to the discovery of a number of putative p21-regulated factors. We further validated three p21-regulated proteins observed at 10.2, 11.7 and 13.4 kDa. Using Q Ceramic HyperD fractionation columns, we were able to selectively enrich for each of these three proteins. Subsequent SDS-PAGE and MS analysis of tryptic digests identified the 13.4 kDa protein as cystatin C and the 10.2 kDa protein as pro-platelet basic protein (PPBP). Judging by the apparent MW and the pI of the 11.7 kDa protein, we reasoned that it may be beta-2-microglobulin, which was confirmed by subsequent identification. Increased levels of cystatin C and beta-2-microglobulin in conditioned media from p21-expressing cells was confirmed by antibody capture experiments using anticystatin C and anti-beta-2-microglobulin antibodies on preactivated PS-20 arrays. Western blot analysis demonstrated increased expression of intracellular and extracellular cystatin C and beta-2-microglobulin in p21-expressing cells, compared to noninduced controls. Increased levels of PPBP were validated in cell lysates from p21-expressing cells. The three secreted factors that we have identified in this study, have all been shown previously to have growth modulating effects and, as such, may contribute to the observed mitogenic and anti-apoptotic paracrine activity of p21-expressing [corrected] cells.

Tumor suppressor maspin is up-regulated during keratinocyte senescence, exerting a paracrine antiangiogenic activity.

Cell senescence is a physiological program of terminal growth arrest, which is believed to play an important role in cancer prevention. Senescent cells secrete multiple growth-regulatory proteins, some of which can affect tumor growth, survival, invasion, or angiogenesis. Changes in expression of different senescence-associated genes were analyzed in cultured human skin keratinocytes (KCs) that underwent replicative senescence or confluence-induced accelerated senescence. Senescent KC cultures showed a strong increase in mRNA and protein expression of maspin, a member of serine protease inhibitor family and an epithelial cell tumor suppressor with anti-invasive and antiangiogenic activities. Immunohistochemical analysis of 14 normal human skin samples (age range from 3 months to 84 years) showed that maspin is expressed by KCs in vivo and that the extent and intensity of maspin expression in the skin is significantly (P = 0.01) correlated with chronological age. Antiangiogenic activity of maspin secreted by senescent KCs was investigated in vitro by testing the effect of conditioned media from different KC cultures on endothelial cell migration in the presence or absence of several angiogenic factors. Media conditioned by senescent cultures (undergoing replicative or accelerated senescence), but not by proliferating KCs, strongly inhibited the stimulation of endothelial cell migration by all of the tested angiogenic factors. Neutralizing antibody against maspin abrogated this effect of conditioned media. These findings indicate that senescent KCs exert a paracrine antiangiogenic activity, and maspin is the principal contributor to this potentially tumor-suppressive effect of cellular senescence.

Identification of potential anticancer drug targets through the selection of growth-inhibitory genetic suppressor elements.

To identify human genes required for tumor cell growth, transcriptome-scale selection was used to isolate genetic suppressor elements (GSEs) inhibiting breast carcinoma cell growth. Growth-inhibitory GSEs (cDNA fragments that counteract their cognate gene) were selected from 57 genes, including known positive regulators of cell growth or carcinogenesis as well as genes that have not been previously implicated in cell proliferation. Many GSE-cognate genes encode transcription factors (such as STAT and AP-1) and signal transduction proteins. Monoclonal antibodies against a cell surface protein identified by GSE selection, neural cell adhesion molecule L1CAM, strongly inhibited the growth of several tumor cell lines but not of untransformed cells. Hence, selection for growth-inhibitory GSEs allows one to find potential targets for new anticancer drugs.

Identification of promoter elements responsible for transcriptional inhibition of polo-like kinase 1 and topoisomerase IIalpha genes by p21(WAF1/CIP1/SDI1).

Induction of p21 (WAF1/CIP1/SDI1), a physiological mediator of cell cycle arrest, inhibits multiple genes involved in cell division. We have investigated the determinants of p21- mediated inhibition of two of these genes, polo-like kinase 1 (PLK1) and topoisomerase IIalpha (TOPO IIalpha) p21 expression from an inducible promoter in human HT1080 cells rapidly decreases cellular levels of PLK1 and TOPO IIalpha promoters in transient and stable transfection assays. Promoter mutagenesis studies show that inhibition of the PLK1 promoter by p21 is mediated in part by tandem sequences CDE (cell cycle-dependent element) and CHR (cell cycle genes homology region). p21 response of the TOPO IIalpha promoter inhibition and the effects of promoter mutations differ under the conditions of growth arrest produced by p21 induction or by mimosine, a cell cycle inhibitor that increases p21 RNA but not protein expression in HT1080 cells. These results indicate that inhibition of cell division-associated genes by p21 is mediated by different but overlapping mechanisms, which are not a general con-sequence of cell cycle arrest.

Retinoid-induced growth arrest of breast carcinoma cells involves co-activation of multiple growth-inhibitory genes.

Retinoids are used in leukemia therapy and chemoprevention of cancers. Treatment of MCF-7 breast carcinoma cells with low doses of retinoids induces gradual proliferation arrest with phenotypic markers of senescence. cDNA microarray hybridization and reverse transcription-polymerase chain reaction analysis showed that retinoid-induced growth arrest in MCF-7 cells in associated with strong induction of 13 genes. Four of these genes (IGF-binding protein 3, EPLIN, beta IG-H3 and FAT10) have antiproliferative activity; EPLIN and beta IG-H3 are also known to be selectively inhibited in transformed relative to normal cells. The functions of the induced genes may also account for other cellular effects of retinoids, including the proteasome-mediated protein degradation, increased cell adhesion, and retinoic acid synthesis. Only one of 13 strongly induced genes (ring finger protein TRIM31) contains a putative retinoid response element in its promoter; TRIM31 also shows the most rapid kinetics of induction by retinoids. In contrast, the antiproliferative genes contain no identifiable retinoid response elements in their promoters and show more gradual induction kinetics, suggesting that these genes are indirectly induced by retinoids. Elucidation of the mechanisms that mediate co-induction of growth-inhibitory genes in retinoid-treated cells may suggest an approach to reproducing the growth-inhibitory effect of retinoids in retinoid-insensitive human cancers.

Molecular determinants of terminal growth arrest induced in tumor cells by a chemotherapeutic agent.

Treatment with chemotherapy or radiation is not invariably cytotoxic to all tumor cells. Some of the cells that survive treatment recover and resume proliferation, whereas others undergo permanent growth arrest. To understand the nature of treatment-induced terminal growth arrest, colon carcinoma cells were exposed to doxorubicin, and surviving cells were separated into proliferating and growth-arrested populations. Only growth-arrested cells displayed phenotypic markers of cell senescence and failed to form colonies. Gene expression was compared between senescent and proliferating fractions of drug-treated cells by using cDNA microarray hybridization and reverse transcription-PCR. Drug-induced senescence was associated with inhibition of genes involved in cell proliferation and with coinduction of multiple intracellular and secreted growth inhibitors. Several tumor suppressors and other genes that are down-regulated in carcinogenesis were up-regulated in senescent tumor cells. Induction of most growth inhibitors was delayed but not abolished in cells with homozygous knockout of p53, in agreement with only limited p53 dependence of drug-induced terminal growth arrest. On the other hand, senescent cells overexpressed secreted proteins with antiapoptotic, mitogenic, and angiogenic activities, suggesting that drug-induced senescence is associated with paracrine tumor-promoting effects. About one-third of the genes up-regulated in senescent cells and almost all of the down-regulated genes showed decreased or delayed changes in p21(Waf1/Cip1/Sdi1)-deficient cells, indicating that p21 is a major mediator of the effects of p53 on gene expression. Elucidation of molecular changes in tumor cells that undergo drug-induced senescence suggests potential strategies for diagnostics and therapeutic modulation of this antiproliferative response in cancer treatment.